Transmission of electrical signals having direct current components



p 1943. A.D. BLUMLEIN 2,328,946 TRANSMISSION OF ELECTRICAL SIGNALS HAVING A DIRECT CURRENT COMPONENT Original Filed March 20. 1936 4 Sheets-Sheet 1 M/VENTOR {ILA/v DOM ER BLl/MLE/N ATTORNEY Sept. 7, 19 43. A. D. BLUMLEIN TRANSMISSION OF ELECTRICAL SIGNALS HAVING A DIRECT CURRENT COMPONENT 4 Sheets-Sheet. 2

' #WENTOR am/Q1251? BLUMLE/N Original Filed March 20, 1936 AFTORNEY Sept. 7, 1943. A BLUMLEm 2,328,946 TRANSMISSION OF ELECTRICAL SIGNALS HAVING A DIRECT CURRENT COMPONENT Original Filed March 20, 1936 4 Sheets-Sheet 3 INVENTDR ALAN DOWERBLUMLE/N 7%! ATTORNEY Patented Sept. 7i, 1943 TRANSMISSION or nmo'raroar, 'slomns HAVING nnmo'r CURRENT oomonanrs Alan D. Blumlein. Ealing, London, England,- assignor to Electric & Musical Industries Limited, Hayes, Middlesex, England, a .company of Great Britain Original application March 20, 1936, Serial, No.

69,831, now Patent No. 2,224,134, dated December 10, 1940. Divided and this application November 19, 1940, Serial No. 366,244., In Great Britain March 20, 1935 3 Claims. (Cl.1 78--7.3)

The present invention relates to apparatus for handling electrical signals having adirect current component and comprises a division of my parent Patent No. 2,224,134, issued on December ent invention to provide improved means whereby compensation for varying attenuation in a system of signal transmission by carrier wave can be obtained, irrespective of whether the di- 10, 1940. The term direct current component" 5 rect current component -ofthe signals is repis intended to include not only the actual direct resented in the transmitted carrier or not. current component but also signal components The present invention accordingly provides a of very low frequency, which may be regarded as method of correcting for the complete or partial slow variations in the actual direct current comabsence of the D. C. component, or for the inponent. In television, for example, the direct correct representation of that component,ineleccurrent component represents the average brighttrical signals representative of intelligence, which ness of the picture transmitted and slow changes method comprises employing an observing dein the average brightness. vice to develop a corrective signal which varies It'is already known, for example,- as indicated in magnitude in accordance with variations in in Williams Patent No. 2,252,746, issued on August the magnitude of said D. C. component, causing 19, 1941, that when a signal having a D. C. comsaid intelligence signal to be effective on said ponent is passed through a channel, such as an observing device only at spaced intervals of time A. C. amplifier, which is incapable oftpassing and utilising said corrective signal to establish the D. C. component, that component is wholly the appropriate eempenent in Said intellior partly lost; it is then necessary, in order to genes si na restore the signal to its original form, to reinsert The invention further provides a method of the lost D, C. component. correcting for variations in'the effective ampli- Means have already been proposed for eflecttllde electrical Signals pres nt v of ining this reinsertion, and it is an object of this tellig 1 11 s may arise in. h t i i n invention to provide novel or improved means of said signals as a result of the complete 1 for this purpose. The invention also aims to par ial loss. of the-D. C. component of said si provide in ans for correcting for the inc rr ct, nals, the incorrect representation of that comrepresentation of the D. 0. component in elec-- 9 Varying attenuation the s trical signals. which. method comprises transmitting along the Furthermore, where signals having a, dir t channel through which the intelligence signals current component are transmitted by modulated e P at Spaced intervals, check Signals each carrier wave, it is not possible'to make use'at f which has a first por on nd a datum P r n a receiver of the average amplitude of the rewhich, at the inputof said ch nn has a P ceived carrier in order to correct for varying determined fixed amplitude Value; a d attenuation, due for example tofading, as is points in said channel, utilizing the second porcommonly done in automatic gain control sysof each of s check Signals to C e-9J1 tems for sound broadcast receivers. This is beobserving device ro a o y i se sitive concause the average carrier amplitude changes at dition to a condition in which it is respo i e thetra'nsmitter not only with changes in attenurthe o respond n datum po on, caus n s d ation but also with changes in the value of the 40 datum portions to influen e s observing, edirect current component, .vice to. develop a corrective signal dependent upon some dimculty therefore arises in providing the i ude of said tu po and pmeans for compensating for varying attenuation, plying, said corrective signal at a point either The difliculty does not, of course, arise where before 1 after the observing po nt o compensate thedir'ect current component is lost or suppressed wholly r in P r s variations in ffec ive at the transmitter but, to obtain the original sigamplitude. l nal at the receivenit is then necessary to pro- TWO sets Q1 Signals are regarded as t a smitted vide some means ior re-inserti'ng themissing. along the same channel either when they are direct current component; The use or a stabiused to modulate th se-me carrier W v 0121f a lised carrier, that one bearing the appropricarrier is not used, when they are transmitted ate direct current modulation, ishowever of ad; along the same transmission line. Thecheck vantage in that for'a given depth of modulation signals may be apart of the intelligence signals the average carrier power can be made lower themselves, .or they may be interposed between than when the carrienis-unstabilised, l" a trains of theintelligence signals. V

It is accordingly a furtherpbject'of the res": 56 The invention also provides a transmission system for transmitting electrical intelligence signals containing a direct current component and a recurrent check signal which has two portions of different amplitudes, the amplitude values of said portions in the signals to be transmitted being substantially fixed when said direct current component is present, said system comprising atransmitter having means for transmitting said intelligence signals, such for example as by modulated carrier, deprived of the whole or a part of said direct current component, and a receiver having means for adjusting the effective gain of an amplifier thereof in dependence upon variations in the difference between the amplitudes of said two portions.

A receiver for use with the system according to the preceding paragraph therefore has means responsive to the difference between two recurrent amplitude values for adjusting the gain of an amplifier thereof. The receiver may be provided with means for re-inserting the direct current component with reference to one of said amplitude values (for example in the Patent No. 2,252,746, supra), and means for thereafter deriving a gain controlling voltage from the amplitude of the other of said amplitude values.

The invention will be described, as applied by way of example to television, with reference to the accompanying drawings, in which Figures 1 to 3 are explanatory diagrams.

Figures 4, 5 and 6 are circuit diagrams illustrating parts of apparatus according to this invention.

Figure 7 is a circuit diagram illustrating a further form of the present invention.

Figures 8 and 9 are further explanatory diagrams.

Figure 10 shows a further circuit arrangement illustrative of a feature of the present invention.

Figure 11 illustrates a part of apparatus for carrying the invention into effect, and

Figure 12 shows a further form of apparatus according to the invention.

Figure 13 is a schematic diagram of a system embodying known transmission apparatus, and the apparatus of Figs. 4 and 5.

Figure 1 shows a form of television signal which may be used in carrying out the present in vention. Picture signals I are interspersed with line synchronising impulses 2, occurring between the scanning of adjacent lines of the object to be transmitted. The line markedW indicates the picture signal amplitude representative of the brightest element of the object, the line marked B corresponds to the amplitude level of a black signal and the synchronising impulses are seen to be in the blacker-than-black" direction.

The dotted line 3. indicates the end of the last line of one traverse or frame of the object and the dotted line 4 indicates the commencement of the next frame. In this interval there is-transmitted a frame signal comprising, in the present example, three pulses 5. The leading edges L indicate the commencements of the line impulses and the leading edge F that of the frame signal. The line impulses and the frame signal serve to control the generation of saw-tooth oscillations at the lineand frame frequencies respectively in known manner. The particular form of frame signalshown in Figure 1 is intended for use in interlaced scanning where the lines traced in one traverse of the image interlace with the lines traced in the next traverse; in thepresent example the image is completely scanned in two traverses thereof and in such a case it is desirable that the broad pulses 5 constituting the frame ing edge L1 is provided in the present example.

The signal of Figure 1 will be assumed to have been used to modulate a carrier in such a way that the direct current component is present at the modulating point, so that any given value of ordinate in Figure 1 will correspond to a fixed carrier amplitude. Further, the modulation will be assumed to have been so effected that the carrier amplitude is reduced substantially to zero on the peaks P of the synchronising. pulses.

Referring now to Figure 4, it will be assumed that there is applied from a suitable radio receiver to the tuned circuit I I the modulated carrier referred to in the preceding paragraph. It will further be assumed that the carrier is subject to varying attenuation and that it is desired to' correct for this at the receiver.

The signals developed across the circuit I4 are rectified by the diode rectifier 6 giving a rectified signal across a condenser I and resistance 8. The time constant of these elements I and 8 is so short that the voltage across condenser I follows the envelope of the modulating signals; in fact, a voltage wave of the form shown in Figure 1 will be set up across condenser I. The rectified signals so obtained are taken through a radio frequency choke 9 and high resistance I0 to the control grid of valve ll. With negligible radio frequency signal (on the peak of a synchronising pulse) this valve II is biased to anode-current cut-ofi by the battery I2. For any signal of about black amplitude, or greater, the valve II is conducting and keeps a condenser I3 discharged. During the synchronising pulses 2 and 5, the condenser I3 charges through a resistance I5, and during a long frame pulse 5, sufficient charge is accumulated on the condenser I3 to take the potential of-- the control gridof a valve I6 to a value above that corresponding to anodecurrent cut-01f; battery I'I serves to bias the control grid of valve I6, and the valve II serves to provide a positive pulse on the grid of valve It at the occurrence of the first frame pulse 5. The anode of valve l6 and the screen grid of a valve I9 are fed through-a common resistance I8. Valves I9 and 20 are connected as a multi-vibrator," their grids being cross-connected to their anodes through condensers 2| and 22 and being connected to earth through leak resistances 23 and 24. The condenser 2| is of comparatively large capacity so that, with resistance 23, it forms a circuit having a time constant which is long compared with the frame period, that is, the time interval between successive occurrences of the leading edge F of Figure 1. The leak 24 is made adjustable. The multivibrator tends to seek its relatively more stable condition in which valve I9 is conducting and valve 20 insulating. The first series of frame pulses 5 (Fig. 1) which arrives makes valve II insulate for long enough to allow condenser I3 to charge up sufficiently to make valve I6 conductive. This lowers the potential of the screen grid of valve I9 and makes makes this .valve' conduct, and the control grid of valve I9 is driven negative. After a, short period, the charge on condenser 22 leaks away through resistance 24 and valve l9 becomes con-- ductive once more, driving valve 20 to a non conductive'state in which, owing to the long time constant of elements 2| and 23, it remains until the next series of frame impulses arrives.

By suitably adjusting the value of resistance 24 it can be arranged that the valve l9 remains insulating for nearly 'as long as the interval between frames, that is, the interval between lines 3 and 4 in Fig. 1. The interval during which the valve I9 is insulating may thus commence during or just after the" arrival of the first pulse 5 and may end just before the picture signals commence again, for example, during the last line impulse of the interval between successive frames. 'A'suitable insulating interval isthat indicated betweenlines 25 and26 in Fig. l.

The circuit of Fig. 4 is-illustrative of circuits which may be used to develop a control signal which can in turn be used "to render sensitive 21 and 28, the signal at the .former point being in the positive sense and that at the latter in the negative sense. The form of the control signal developed at 21 is shown in Fig. 2.

A part of a correcting device according to the invention which is suitable for use with the arrangement of Fig. 4 is shown in Fig. 5. The received carrier is applied as in Fig. 4 to a tuned circuit l4 and is demodulated by a diode detector -6 having a condenser I with a parallel load resistance 8 connected as shown. The elements l4, 6, 1 and 8 need not be duplicated in the circuit of Fig. 5 because, if desired, the requiredvoltages may be taken from the terminals of condenser I of the apparatus of Fig. 4, in which case it is to be noted that the cathode of valve 29 of Fig. 5 is conductively connected to .earth through batteries, '35, |2fand l1. Voltages mayalso be taken, if desired, from the same terminals to supply the. picture reconstituting device. Alternatively, some or all of the elements referred to may be separate for the different parts of the receiver circuit, inwhioh case the negative end of battery 35 of Fig. 5 should be earthed.

.The wave form of the kind shown in Fig. 1, developed across the condenser I of-Fig. 5, is fed to-the outer control grid of a hexode mixer valve 29. Positive pulses, such as those shown at 32 in Fig. 2 which may be derived from point 21 in Fig. 4; are applied at 30 through a condenser 3| to the inner control grid of the valve 29. The

. inner control-grid is, suitably biased through a leak 33, and the bias valvemay be so adjusted. that the inner grid'comes to cathode potential during each pulse 32 but falls inthe intervals between pulses 32 to such a negative value that the-valve 29 is then entirely inoperative. By giving the biasvoltage a value slightly less negative than required for the above purpose, it can be arranged that the grid automatically fixes itself during the pulse at aboutcathode potential,

owing to grid current charging the feed condenser 3|. The outer controlgrid of valve 29 is biased by a battery 35 so that with negligible incomingradlo signals (peaks P of the synchronising pulse) the outer control grid will cut oil or at least very considerably reduce the anode current, even if the inner control grid is at cathode potential. When, however, a signal representing black occurs, the outer grid will allow curent to flow to the anode whenever the in-- ner grid allows the valve to conduct. The anode current of the valve 29, during periods in which the inner grid allows the valve to conduct will have a wave form which is the same as that of the part of the signal of Fig. 1 between dotted lines 25, 26, while at all other ,times the anode current will be zero or substantially zero.

Fig. 3 shows the wave form of the anode current of the valve 29. The dotted parts of the curve show the currentthat would-be obtained were the inner grid switched on all the time, and the full line part of the curve shows the actual anode current. In order that the valve 29 may operate efficiently, it can be arranged that the outer grid is arranged to be at approximately cathode potential for a signal representing blackamplitude. Although the picture signals. will drive the outer grid more positive than the cathode, no grid current will flow, since the valve The magnitude of the D. C. component of the V anode current of valve 29 will vary in accordance with variations in the amplitude representing black, and the voltage across the anode resistance 34 may therefore be used, after smoothing to provide a D. C. potential for operating controlling devices, e. g., variable-mu valves for automatic gain control.

. Alternatively, the A. C. component of the anode curent may be passed out through a condenser 36 and may be amplified to provide an A. C. controlling wave.

Figure 6 shows a circuit, employing the latter method, by which the A. ,C. controlling wave referred to may be utilized. Thesignals taken 0!! through the condenser 36 of Figure 5, after amplification if desired, are fed from terminal 4|, through condenser 42, to a resistance 43. The signals should be fed in at 4| in such awaythat the pulses in the-direction P to B in 'Figure 3 during the frame interval are in the negative direction. The A. C. voltage set up across resistance 43 is fed to a diode rectifier 44, which, owing to the values chosen for the condenser 45 and the load resistance 46, operates as a peak rectifier. Any alteration in the blackamplitude of the'incoming signal (that is, of the level B in Figure 3) will'introduce a change in the amplitude of the AC. wave fed in at 4|, and a corresponding change in the rectified voltage set up across condenser 45. The rectifier -44 is shown so connected as to produce a negative potential at the upper terminal of condenser- 45 'with'respect to-earth. By providing suitable. amplification between 'the-valve'29 of Figure 5 and the a small change in the black amplitude produces a very large change in rectified voltage set up across condenser 45.

If it is required to hold the resultant signal to fairly close limits, a battery 41 may be inserted 5 in series with the rectifier, so as to prevent rectification taking place until the black signal reaches a predetermined value. Any small in crease in the black signal will then produce a comparatively large negative voltage across the unsteady state arising in which the apparatus as a whole might tend to "hunt." In any case, the time constant of condenser and leak resistance 46 should preferably exceed by several times the time interval between successive frames. As the leak resistance 46 may have a relatively high 25 value, it may be desirable to pass the rectified voltages through a further valve (48, Figure 6) before utilization, in order to ensure that leakages in the utilization circuits do not afiect the voltage across condenser 45. The valve 48 has so its anode connected to a. suitable source of high tension (not shown), and its cathode fed from a negative voltage source (not shown) through a comparatively high resistance 49. The voltage most exactly the voltage of the grid of that valve, and the voltage on the cathode can be utilized at for any required purpose. For example, the

' connection 50 may be taken to provide the bias for the grids of variable-mu valves in the radio- 40 lized for re-inserting the direct current component into the signals, assuming that the signals are not subject to varying attenuation. For example, suppose that television signals are fed through an amplifier channel of steady amplification which does not however transmit the direct to current component. Such signals may be fed in to a circuit such as shown in Figure 5 at the point 31 (the radio frequency rectifier 6 being omitted). As before, signals are fed in at 30 to render the'valve 29 responsive for a period during the interval between frames. The direct component of the anode current of valve 29 is then proportional to the absolute amplitude of the black pulses fed into this valve, and thepotential drop across-the resistance 34 in the-anode circuit due to this direct component may be utilized to re-insert the D. 0. component of the signals fed in at point 31. These signals are preferably fed in at 3'! through a condenser, the grid to.

which they are applied being connected through a leak resistance to the cathode of valve 29. The anode circuit resistance 34, shunted by a condenser, is then conveniently arranged between.

the cathode of the valye 29 andthe negative terminal of the anode current source (not shown) If it is arranged that a 15 ill and the potential of the cathode is applied through a. grid leak to the control grid of a subsequent valve to provide a bias therefor; in this arrangement, it should be arranged that only the anode current, and not the screen grid current of. valve 29 passes through the resistance 34,-and this can be achieved by supplying the anode and screen grid from different current sources. Black level is then represented by a potential at the cathode of valve 29 which is positive with respect to earth, and which can be employed to bias the control grid of a further valve to which the alternating component of the signal is fed in a sense opposite to'that of signals fed to valve 29. In another arrangement, the

cathode of valve 29 is earthed, and theanode' resistance 34 is inserted between the cathode and the negative terminal of a source of current which is arranged to supply the anode but not the screen grid; grid bias for the further valve can then be taken from the junction point of resistance 34 and the anode current source.

The signals fed to the further valve mentioned inthe preceding paragraph may be obtained from I lead 31 of Figure 5, and another valve may be inserted if desired to reverse the phase of the signals. The magnitude of the direct component of the potential difference set up across resistance 34 may be adjusted so as to ensure correct reinsertion of the D. C. component by adjustment of the value of resistance 34.

In a further example of the use of this invention, atelevision wave such as that shown in Figure 1, is transmitted through a channel of the cathode of the valve 48 will then follow al- 35 wherein, although the absolute gain for the picture signals is substantially constant, the D. C. component and the amplification of the synchronising pulses vary owing to the variations say of H. T. voltage and the effect of curved amplification characteristics.

An example of such a use will'be described with reference to Fig. '7. This fi'gure represents a typical form which the input circuit to the modulator of a transmitter for television signals may take. The amplified television signal wave such as is shown in Fig. 1 is fed in at 5| through a condenser 53 to the grid of a modulator 52. The sense of this wave is such that the picture signals are negative and the synchronising signals positive.' The grid of the valve 52 is connected to the cathode through the leak 54, and this leak,

together with a diode 55, serves to re-establish the direct current component of the applied signals on the grid of valve 52 with reference to the peak values P of the signals. The absolute value of the voltage of the grid 52 which represents the across resistance 58 thus contain their direct our rent component. The upper end of resistance 58 is connected through a source 59 for providing the desired bias voltage to the grids of two pushpull connected triode modulator valves 60; the grids of these valves are fed with radio frequency oscillations of carrier frequency through the coils 6i and $2. The radio frequency output from the anode of the valves 60 is then passed through transmitter.

nisin signal input allows for the curvature 01! further radio frequency amplifiers (not shown) if required, to the aerial. v

[he wave form of the signals fed in at BI is such that the ratio of synchronising signal am:

plitude to picture signal amplitude is larger than is required in the final modulated output of the This relative increase of synchrocharacteristics. Since the synchronising signals are of 'a substantially square-topped wave form, there will be no wave-shape distortion other than a relative attenuation due to the operation over the curved part of the modulator characteristic, so that this part of the characteristic can be used. for the synchronising signals, leaving the upper straighter part for the picture signals. The resultant radio-frequency output at the aerial of the transmitter has then a range of values corresponding to particular light intensities in the object of which an image is to be transmitted, and a value, substantially equal to zero, corresponding to the peaks of the synchronising signals. Although this latter value is normally zero,

parts of thecharacteristics of the receiver valves, it is impossibleto keep constant the amplitude of the peaks P of the synchronising pulses with respect to black B because different peaks will extend to difierent extents along the said curved parts; the correct re-insertion of the D. C. com-.

ponent with reference to the peaks P is thus rendered impossible. It is therefore diflicultto maintain a correct representation of the average picture brightness at the receiver and, when the variations in question are considerable, it may prove difficult to separate the synchronising signals correctly from the picture signals.

In order to correct for variations of the kind above described, therefore, it'may be arranged, according to a featureof the present invention, to feed in at point 56 in Fig. 7 a voltage which varies in such a manner as to keep the black" level of the carrier output at a constant value in spite of the variations referred to.

One way in which this may be done isto feed modulated carrier frequency energy from the transmitter of Fig. 7, Or from the transmitting aerial, to the circuit H of an arrangement such as that of Fig. 5 Signals of the form shown by 32 in Fig. 2 are applied at point in Fig. 5.

. These signals may, for example, be generated it is often inconvenient to provide suflicient synchronising signal input to modulate the transmitted carrier fight down to zero amplitude by swinging the modulator around the bottom bend of its characteristic.

At the receiver, correct representation of absolute brightnesses is obtained either by providvalve 29 may-.therefore be fed, after any .necessary amplification to terminal 4|, and thence into a the device of Fig. 6; here, as already explained, there are developed across resistance-l9 voltages I which can be arranged to vary substantially with chronising pulses and black varies, the direct current or average picture brightness component will eifeotively vary at the receiver. For example, a slight fallof the carrier value representing black, or the amplitude of the synchronising pulses relative to black, will cause the screen of the cathode ray tube to be darkened. Such darkening will berelatively unimportant in the high lights, but may be sufflcient to obscure detail in the dark be caused for example by variation in the voltage of the source supplying the anode circuitsoi the modulator or radio frequency amplifiers at the transmitter, or by variation in the voltage of battery 51 in Fig. 7. The efiect of the variation at the receiver will be the same whichever of the two vmethods,above referred to, of ensuring that the D. 0. component is present at the light-modu- Iati'ng device is used. Unless the carrier amphtude representin'g'black remains constant, and if the synchronising .pulses extend over the curved relatively small variations in the level corresponding to black in the signals fed in at 31 -in Fig. 5.

The output obtained at point 50 in Fig. 6 may then lie-applied to control the potential-of point 56 in Fig. 7. In the particular arrangement shown in Fig. 6, an increase in blac amphtude produces a negative voltage at 50, whereas a positive voltage is required at point 56 of Fig. 7 in order to correct such an increase in amplitude. To overcome this difficulty, the sense of the input to the diode 44 in Fig. 6 may be made opposite to that previously described; the diode and battery 41 are then also reversed. The point 5.0 in Fig. 6 may then be connected, by means of a direct-current connection which may. if necessary include a source of biasing potential, to

point 56 in Fig. 7 to give the desired result.

Alternatively, there may be applied to point 56 of Fig. 7 a voltage proportional to the direct component of the current flowing in the valve 28 of Fig. 5; this may be achieved, for example, by inserting a resistance in the cathode circuit of the valve 29, as described above in connection with the reestablishment of D. C., and the catode of th valve 29 may then be connected to point 56 of Fig. 7.

Instead of injecting the control voltage at point 56 of Fig. '7, it can be arranged that the potential at point .50 in Fig. 6 is effective in con- :'trolling the amplitude of the synchronisingsigthe picture signals, they may be passed through by variation in the bias of one or more variablemu valves, a lead may be taken from the point 50 to the control grids of these valvesin order to control the bias thereof. In such an arrangement, the apparatus of Figure 6 is connected up as shown, and signals are applied at point II in the same sense as that mentioned in the original description of that figure. An increase in black amplitude accordingly produces a negative voltage at point 50, tending to reduce the amplification of the synchronising signal amplifier and thus tending to reduce the black amplitude.

In a system inwhichthe carrier amplitude is not reduced to the neighbourhood of zero on the peaks of the synchronising signals, it can be arranged that the black signals alone are efiective in producing a voltage for controlling the black level. Such an arrangement, would not take count of changes in the amplitude P to B in Figure 3 unless such changes were accompanied by changes in the black level. This result can be obtained with the circuit of Figure 5 by biasing the valve 29 so-that the synchronising signals carry the outer control grid well below cut-ofi, so that variation in the amplitude of the synchronising signals is not effective in changing the anode current. The anode current is then controlled in accordance with changes in'the amplitude of the black signals (B Figure 3).

Where it is undesirable or inconvenient to apply a correction to thesynchronising signals before they are mixed withthe picture signals, the synchronising signal amplitude maybe increased or decreased relatively to the picture signal amplitude by passing thev composite signal comprising mixed synchronising and picture signals through a suitable circuit. Such a circuit may comprise a thermionic valve, the curvature of the characteristic of which can be varied under the control of a voltage such asthat obtained from point 50 in Figure 6. An example of a circuit of this kind is shown in Figure 10. The composite signal having the form shown in Figure 1 for example, is fed through a condenser II on to the grids of two valves '14 and the signal fed in loses its D. 0. component, if that .component is present, in its passage through condenser H. The sense. of the signals is such that the synchronising signals are positive. A diode l2 and leak 13 serve to re-insert the D. C. component into the signals with ref: erence to the peaks P of the synchronising signals. The cathode of valve 14 is connected to earth through a resistance 18 which reduces the mutual conductance of the valve and'lengthens and straightens. its characteristic. The valve 15 has its cathode biased very positively so that black In the systems so far described, the corrective eiTect is derived from an "observation of the level during the intervals between frames.

Where'the line synchronising'signals do not occupy the whole of the interval between sucthe valve is inoperative for the negative picture signals on its grid but is operative to give increased amplification for the synchronising signals. The combined output of the valves 14 and 15 is passed out at I6.

A control voltage, such as that from point 50 in Figure 6, is. applied at point 11 and is efiective in altering the bias on thevalves 14 and 15. .Thus an increase. in the black level of the outgoing signals will produce a negative voltage at-TI which will reduce the amplitude of the synchronising signals, so tending to neutralise the change in black level.

cessive trains of picture signals representative of successive linesof the object, however, use may be made of an observation in this interval (which may be called the line interval) to derive a corrective effect. A line synchronising impulse usually occupies about one tenth of a line period and the other nine tenths is usually occupied by picture signals.

In Figure 8 is shown a Wave form in which the line synchronising impulses 2 occupy only a fraction of the line interval D, for example a quarter of this interval. Thus the impulse lasts for one fortieth of a line period and during three fortieths cf a line period the signal is at black, indicated by reference B. With such a signal it is possible to derive a corrective effect once every line and a more rapid control is therefore possible than with the signal of Fig- -ure 1. Signals of the kind shown in Figure 8- may be useful for example for providing automatic gain control for the receiver of a relay station receiving signals from a moving transmitter, for instance of the type which may be used in moving vehicles, or over some other channel subject to rapidly.varying attenuation, with a view to retransmitting the signals after correction. If the maximum possible rapidity of action is desired with signals of the kind shown in Figure 8, the signalsin the frame interval should preferably diifer from those shown in Figure 1. Thus each of the pulses 5, Figure 1, may be constituted by an excursion (as F, L and L1) to level P to form a pulse lasting one fortieth of a line period, a return to level B for an interval of three fortieths of a line period, a further excursion to level P for a time equivalent to three tenths of a line period followed by a return to level B.

The signals of Figure 8 may be utilized in a circuit which is a modification of that shown in Figure 4. In the modification, the valve II and resistance L0 are omitted and the output of the rectifier 6 is taken from the choke 9 to the grid of the valve l6. Further, the rectifier 6 is inverted, so that picture signals produce a rectified voltage in the negative sense.v The valve 16 is so adjusted or biased that it does not pass current for the negative voltages representing picture signals. At the occurrence of a line synchronising signal however, the valve I6 conducts, thus triggering the multi-vibrator comprising valves 19 and 20. The leak 24 is adjusted so that the valve l9 remains insulating from the moment of triggering to just before the beginning of the next train of picture signals, that is for most of the one-tenth of a line period. Instead of making the condenser 2| so large that the multi-vibrator is quasi-aperiodic, it may be found advantageous to make the natural period of the multivibrator just longer than a line period, so that the device tends to run at the required frequency. The amplitude tof the pulses required from valve I6 is thus reduced. The output at points,2l and 28 then takes the form of pulses occurring at the line frequency, each pulse having a length slight- 1y less than one tenth of a line period.

The pulses from point 28 may be fed in at point 30 to the apparatus of Fig. 5, and may control the valve 29 to give output signals at 36 dependcut on the black amplitude occurring in the short interval between a line synchronising pulse and the beginning of the picture signals of the next line. The signals set up at point 36 may be amplified and passed to a circuit such 'as that of Fig. 6 for producing a control voltage at 50. In this case, the time constant of condenser 45 and leak '46 may be made much smaller than that employed for observation once per frame, so

that a more rapid control is obtained. The time constant of elements 45 and 46 should, however.

Similarly, a wave form may be employed in which, during the interval between a line syn- 'chronising signal and the picture signals of the next succeeding line, the signal amplitude corresponds to a value within the picture range,

' say halfway between black B and white W.

be made sufiiciently greater than the line period to prevent any instability of the control.

The examples given above are of-systems in which the black level is observed" and a corrective signal dependent on this-observation is injected at a point earlier in the system than that at which the observation is made so as to correct as far as possible any variation of black level at the point of observation. The invention is also applicable to systems in which the controlling signal is utilized to correct the black level at some point after the point of observation. For example, in the automatic gain control systems described above, the control signal developed at point 50 in Fig. 6 may be used to control the gain of amplifiers following the point of observation. Alternatively, where large variations of transmission efliciency are to be corrected, it may be arranged that the corrective signal serves to vary the amplification both before and after-the point of observation. For example, the' control voltage at point 50 in Fig. 6 may be'utilized to control the radio frequency amplication ahead of the rectifier 6 in Fig.

such a control may, for example, reduce the a variation of the black level at the rectifier .6 in

Fig. 5 to for a 40 decibel change in incoming signal strength; the control voltage at point 50 in Fig. 6 may also serve to produce a slight variation in the amplification following the ch- Such a wave form provides a strong controlling signal, but it may be found necessary to provide means to "black out" this signal so as to prevent its appearance in the reproduced picture.

Further, a wave of the kind last referred to may with advantage be used in'a system which involves relaying a signal tda final transmitter: after the corrective signal has been derived and used to correct the signal, the excursion into the picture range occurring in'the line intervals may then be suppressed before final transmission of A radio relay station for a television trans'-. mission system may employ the corrective means according to the present invention more than once. For example, the wave received at the relay station may be of the general form shown in Figure 8 and may be observed once per line.

The radio frequency gain may then be adjusted automatically as already described in dependence upon th'observation. A further automatic adjustment of gain may then be carried out in order to correct for the error remaining as a re sult of the fact that slight changes in the black level at the observatiompoint are necessary to servation point (e. g., the modulation frequency amplification following the rectifier) so that a 10% change of black level at the observation point produces a 10% compensating change of gain following it, 'thus ensuring that the final output signal is substantially free from any variation.

The arrangements so far discussed are based on an observation of the black amplitude. The invention can also be carried into effect by an observation of any definite picture amplitude, or of an amplitude related to a definite picture amplitude. For example, instead of the wave shown on Fig. 8, the wave shown in Fig. 9 may be transmitted. In this case, during the interval between the synchronizing pulse and the beginning of the next line, the signal amplitude assumes, a value E which lies between the synchronising peaks 2 and the black amplitude B. Such a signal level may 'be fixed as being a certain fraction of the distance between P and B or, alternatively; if the amplitude of the syndevelop a corrective signal for controlling the gain of a preceding amplifier. The corrected modulation frequency output may be passed through a circuit adapted to increase the relative amplitude of the synchronising signals so as signal of the type shown in Fig. 9 may be useful for direct reception by the use of a'cathode ray tube, the slightly blacker-than-black signals E serving to black out the cathode ray "during the scanning return strokes. Such a signal may be observed by the use of circuits similar to those employed for the wave of Fig. 8, but with suitable modification and adjustment.

.are employed to turn on the observing valve.

of the general form of Figures 8 and 9 or once per frame for waves of thev general form of Figure 1. In a further modified arrangement based upon that described with reference to Figure 4, the

synchronising pulses are again caused to generate the required switching signals, which in turn In the modified arrangement, using the wave form shown in Figure 8 or 9, the synchronising pulses P are separated from the vision signals in the manner described in British Patent No. 422,- 824and in the corresponding U. S. Patent No. 2,194,514, issued to Williams on March 26, ,1940.

, The separated pulses are then suitably delayed by ployed which is, similar to that shown in Figure 8, but which differs in that the synchronising pulse lasts for onte tenth of the line. period while the black interval B lasts for one twentieth of the line period. Signals of this wave-form are illustrated on page 373 of the issue of The Wireless World of the 4th October 1935. The method last described is clearly not applicable here, since the synchronising pulse lasts longer'than the black interval; there is, therefore, employed an alternative method in which the observing valve is turned on by a pulse obtained not from the leading edge of the synchronising pulse but from the trailing edge.

Apparatus for carrying this method into effect is illustrated in Figure 11; signals of the form shown in Figure 8, but with synchronising pulses lasting longer than they black intervals B, are fed in'at 80 through a condenser 8| to a valve 82, it being arranged that the synchronising impulses are in the positive sense on the control grid of valve 82. The valve 82 serves in the manner described in United States Patent 2,194,514,

supra, to separate the synchronising pulses from the picture signals, that is, its control grid tends to assume zero potential at the peaks P of the synchronising pulses, the picture signals lying be'- yond anode-current cut off.

In the anode circuit of valve 82 is a small condenser 83 and a resistance 84 in series, the arrangement being such that differentiated synchronising pulses are set up across resistance 84; at the beginning of each pulse a sharp negative pulse appears at the top of resistance 84, while at the trailing edge of the pulse a positive pulse appears at that point. The positive pulse causes the anode current of a valve 85 to increase; the anode circuit of valve 85 contains a resistance 96, and the potential of the anode of valve 85 consequently falls.

A negative pulse is thus passed to the screen grid of valve 81, which, together with valve 88, forms a multivibrator, and the multivibrator is triggered ofi.

The multivibrator is so adjusted that a positive pulse is set up at the anode of valve 81 during each black interval B, and this pulse may be taken off at 39 and employed to actuate an observing valve, such as valve 29 in Figure 5. It is to be noted that, in the practical wave form referred to above, the framesignals each comprise a plurality of pulses of longer duration than the line .pulses, successive frame pulses being separated by black intervals; the multivibrator is thus triggered off by the trailing edges of both the line and frame pulses, and the observing valve is thus switched on during the black intervals following the frame pulses as well as during those following the line pulses.

If desired, the multivibrator 81, 88 may be omitted, the pulse from valve 85 being broadened by means of a low-pass filter, reversed in sense in an amplifying valve, and fed directly to the observing valve.

A further form of apparatus suitable for use in generating a signal for actuating an observing valve, which is particularly suitable for use fed from the anode of valve 92- to. the inner grid of a hexode 93, where they appear in the negative sense, the arrangement being such that no anode current flows when a synchronising pulse is present'on the inner grid.

The synchronising pulses are also fed, through a delay network comprising series inductances 94 and shunt condensers 95, to a reversing valve 96 having a resistance 91 in its anode circuit. Each synchronising pulse causes a positive pulse to appear at the anode of valve 96, and these positive pulses are fed through condenser 98 to the outer control grid of hexode 93; the outer control grid is connected through a leak resistance 99 to a source of grid bias I00, which serves to hold the outer grid at such a potential that,

normally, no current flows to the anode.

The hexode 93 acts as a switch, the delayed positive pulses from valve 96 tending'to open the switch, and the undelayed pulses applied to the inner grid tending to hold it closed. The delayed positive pulses can thus only open valve 93, and allow anode current to flow therein, in the absence of negative pulses on the inner grid, and the delay introduced by network 94, 95 is made such that the valve 93 isopenedfor a part of the black interval of the signal immediately after each synchronising pulse. The anode circuit of valve 93 contains a resistance I01, and the pulses set up at the anode of valve 93 are taken off at I02, through condenser I03, and fed, after: being reversed in sign, to an observing valve such as valve 29 of Figure 5.

It is to be noted that in all cases any small phase error between the beginning of the pulse fed to the Observing valve and the occurrence of the black level or other signal to be observed may be compensated for by the use of suitable delay networks, which may be inserted either in the channel-feeding the observing valve, or in that part of the apparatus in which the signal for actuating the observing valve is generated.

In the above description, there have been described methods of correcting for varying' atwith a signal of the form shown in Figure 8, but

with synchronising pulses of longer duration than the black interval B, is illustrated in Figure 12. Signals of the form mentioned are fed in at point 98, through condenser 9|, to a valve 92,

which serves the same function, and operates in the same manner as valve 82 of Figure 11. Synchronising pulses, freed from picture signals, are

tenuation or for complete or partial absence of the direct current component of signals. For this it has been shown to be sufiicient to derive a corrective signal dependent upon the received amplitude of a signal which, atthe transmitter,

is a fixed value.

Where, however, it is desired to correct for varying attenuation of signals which have no direct current component, for example, signals w'hich have lost their D. C. component, it is a fixed difference from value '3. Now if such a signal be transmitted through a channel which is incapable of transmitting the D. C. component and which subjects the signals" to varying attenuation, the procedure may be as follows:

The signals are given a datum co-incident with the peaks P with the aid or a, D. C. re-inserting device of the kind set forth in United States Patent No. 2,252,746, for example, and at the same time they are used to derive a corrective signal dependent upon' the amplitude of level B, in the manner already described. As the D. C. re-inserting device ensures that the datum remains on the peaks P and as the corrective signal makes the amplitude P to B substantially correct, the

desired corrections will have been applied.

Although the invention has been described in some detail with reference to its application to television systems it is also applicable to other systems in which signals of the requisite character are either present inherently or are arrangedto be present for the purpose of enabling a corrective effect to be derived according to the present invention.

Referring to Fig. 13, there is shown a schematic diagram of a system for correcting for varying attenuation. The signal at the transmitter is developed by known means, and in this case an object "it is focussed onto the'mosaic of an iconoscope tube IUI, and video signals are developed therefrom. Frame synchronising generator I02 and line synchronising generator I03 fed into a modulator and a signal such, for instance, as that illustrated in Fig. 1, is transmitted. At the receiver a portion of the signal is fed to thecircuit it, which corresponds to the circuit l4 hereinbefore referred to with respect to Fig. 4. No further explanation of the operation of the apparatus which has been ex-. plained hereinbefore with reference to Fig. 4 is thought to be necessary. The signals from the tube l9 and the point 21 identified in Fig. 4 are fed to the tube 29, such as has been explained hereinbefore on page 3. The output of the valve 29, therefore, is used to operate known automatic gain control apparatus which, in turn, is fed to the receiver schematically illustrated as What I claim is:

1. An apparatus for re-establishing the direct current component in a television receiver wherein a composite series of picture signals and periodically recurring synchronizing signals are received, the synchronizing signals being immediately followed by a .-black level signal that varies in amplitude with respect to the altemating current axis of the composite signals in acthe cathode, means for applying the produced short positive impulses corresponding to the trailing edge of the synchronizing impulses to the first control electrode of the'electron discharge tube to render said tube conductive, means for applying the synchronizing and black level signals to the second control electrode of the electron discharge tube, whereby the electron discharge tube is rendered conducting during each black level signal interval to thereby produce a potential at the anode of said dis-' charge tube having an intensity corresponding to the intensity of the black level signals.

2-. Apparatus for correcting for variations in the efiective amplitude of electrical signals representative of intelligence due to the incorrect transmission of the direct current component thereof and wherein said intelligence signals are in the form of trains of signals interpersed with auxiliary signals between trains comprising an observing device including therein a thermionic tube, means for impressing said intelligence signals and said auxiliary signals onto said observing device, means for generating electrical switching pulses, means for impressing said switching pulses onto said thermionic tube for initiating intermittently the development of a signal by said tube whereby a corrective signal proportional to the incorrect direct current component is developed, and means for utilizing said corrective signal to re-insert the correct direct current component. I

3. An apparatus for re-establishing the direct current component in a television reproducing device comprising means for receiving signals having a check portion and a datum portion,

such signals being transmitted between trains of video signals, rectifying means, means for impressing said received signals onto' said rectii'ying means, normally inoperative corrective signal developing means for developing a corrective signal proportional to the amplitude of the datum signal, thermionic means, means for storing electrical energy under the'control of the output of said thermionic means, means for utilizing said'stored electrical energy for providing rect current component by means of said switchins sisna1.

' ALAN n. BLUMLEIN. 

